RU82731U1 - DEVICE FOR REINFORCING REINFORCED CONCRETE PANELS OF overlapping - Google Patents

Abstract

1. A device for reinforcing reinforced concrete floor slabs, including additionally brought steel transverse beams, characterized in that the transverse reinforcing beams are supported on the lower shelves of the longitudinal beams of the building frame, while the transverse beams are summed up from the bottom of the reinforced overlapping panels with a gap between the top of the transverse beams and the bottom of the reinforced floor panels, the cross beams are equipped with screw spacers that are installed in the gap between the transverse beams and the floor panels; after the introduction of the spacers into operation, the distribution stop plates and the transverse reinforcement beams are connected together by segments of corners or plates; the gap between the floor panels and the transverse beams is filled with structural reinforcement concrete in the form of a concrete key with indirect reinforcement; shelves and ribs of steel reinforcement beams are covered with protective materials of the required thickness from the condition of fire resistance of floor beams as load-bearing elements of a building. ! 2. The device according to claim 1, characterized in that the cross-sectional dimensions of the steel rolling profile of the transverse beam are taken from the conditions for calculating the load-bearing capacity of the device for reinforcement during its installation. ! 3. The device according to claim 1, characterized in that the cross-sectional dimensions of the reinforced concrete transverse beam with a steel rolling profile used as rigid reinforcement are taken from the conditions for calculating the load-bearing capacity of the device for reinforcing floor panels. ! 4. The device according to claim 1, characterized in that the screw spacer includes the upper shelf of the steel rolling profile as a support table,

Description

The utility model relates to the field of construction and relates to the reinforcement of reinforced concrete floor panels damaged due to various reasons, including those affected by fire in a fire or accident.

During the fire exposure, reinforced concrete floor panels are heated from below. The maximum heating temperatures (800 ± 200) ° C are observed on the heated surface of the panel and at a depth of 10-20 mm. Concrete and reinforcement in the compressed zone of the section of the panel warm up more slowly and not significantly. Damage to panels by fire includes: a random arrangement of surface heat-shrinkable cracks, destruction of part of a section of a panel heated above a critical heating temperature (600 ± 50) ° С, cracking of concrete, delamination of the concrete protective layer, change in the mechanical properties of heated reinforcement. More severe thermo-force damage to hollow panels is possible: longitudinal and oblique cracks with a width of 3 ÷ 10 mm in the walls separating the hollow channels. As a result, there is a significant decrease in the strength and stiffness of the hollow panels.

The utility model is designed to restore the basic operational characteristics (bearing capacity and fire resistance) of reinforced concrete floor panels.

A device is known for reinforcing fire-damaged floor panels, consisting of additional reinforcement in the form of separate reinforcing bars or bent grids strung on rods of existing reinforcement; / Pat.2 119 023 RU, IPC-6 Е04С 5/08. Reinforcing product / Ilyin N.A .; application No. 96 115 626/03; from 07/26/96; publ. 09/20/98, Bull. No. 26; /[one].

For reasons that impede the achievement of the technical result indicated below when using the known device for reinforcing damaged hollow core panels, the additional reinforcement reinforcement is made discretely in the form of a number of reinforcing elements that are located in the plane of the existing mesh

bottom of the panel. Therefore, the known device is not rational for strengthening hollow panels, is not economical and time-consuming.

A device is known for reinforcing reinforced concrete floor panels in the form of an elastic beam unloading reinforced concrete structural element, which is connected from below and is attached by female clamps to the columns of the building frame and has a supporting stop in the middle of the span. The summed beams are separated from the reinforced element at a distance of 50-150 mm for the convenience of concreting them; the supporting stops are performed after the reinforcing element is dismantled and its elastic subsidence under the influence of its own weight, representing a simple concrete footing of a fixed place of the elastic support (or several supports); / Onufriev N.M. Reinforcement of reinforced concrete structures of industrial buildings and structures. / - L., - M.: Stroyizdat, 1965, -342 s; (see p. 90-91, Fig. 33, a); / [2].

The reasons that impede the achievement of the technical result indicated below when using the known device for reinforcing reinforced concrete floor slabs include the fact that when grasping the columns of the building with fastening clamps, they break off the protective layer of concrete and expose the working reinforcement of the columns to which the covering reinforcing bars of the supplied beams are welded; this leads to shock loads on the structure; concreting bare columns and an additional reinforced concrete reinforcement beam increases the time for the construction of a reinforcement device, reducing the useful height of the premises; amplification elements have unreliable communication with amplified overlap panels; it is impossible to control the amount of unloading of the reinforced floor panels.

The closest technical solution to the utility model in terms of all the features is a device for reinforcing reinforced concrete floor panels, which includes additional summed steel transverse beams with a change in the design of the panels, the width of the beams is accepted up to 100 mm, and the height is 1: 10 ÷ 1: 12 span; / Recommendations on the assessment and strengthening of building structures of industrial buildings and

constructions./NIIISK. - M .: Stroyizdat, 1989, -105 s (see p. 28, p. 4.30, fig. 2, D; p. 35, p. 4.35); / [3] - taken as a prototype.

For reasons that impede the achievement of the technical result indicated below when using the known device for reinforcing reinforced concrete floor panels adopted as a prototype, the fact that punching holes and holes in the supporting sections of reinforced concrete floor panels for installing reinforcing support elements on the upper shelves of panels leads to shock loads and weakening of structures, which can lead to their sudden destruction; the installation of reinforcing elements on top of the panels reduces the useful floor area, increases the working dimensions in height, creates inconvenience in the further operation of the premises served by floor transport or cars; the designs of steel transverse reinforcement beams have an unreliable connection along the width of the reinforced panels and require a large consumption of structural steel; additional closing of concrete with holes and holes in reinforced overlapping panels increases the time of construction of the reinforcement device and the consumption of concrete; the use of steel reinforcement beams without fire protection significantly reduces the actual fire resistance of the load-bearing floor beams.

Therefore, the restoration of the main operational characteristics (bearing capacity and fire resistance) of the floor panels of the known amplification device is neither rational nor qualitative.

The essence of the utility model is as follows:

The problem to which the claimed utility model is directed consists in a rational arrangement of the reinforcement structure, in a more economical restoration of their main operational characteristics, in reducing the volume of emergency recovery work, in reducing the metal consumption for additional transverse reinforcement beams.

EFFECT: high-quality restoration of the main operational characteristics of reinforced concrete panels

overlapping using additional summed elastic supporting transverse beam structures;

as a result of using the utility model it is possible:

a significant increase in the strength and rigidity of floor panels;

a significant increase in the actual fire resistance of the panels on the basis of loss of bearing capacity in a fire;

improving the safety of damaged panels during emergency recovery operations; creation of reliable communication amplified panels and mating elements of the amplification device; eliminating the need for punching through holes and holes in the supporting sections of reinforced concrete floor panels to install reinforcing support elements on top of the panels; smooth unloading of severely damaged floor panels; regulation of the amount of unloading of the reinforced floor panels; the amplification device is easy to design and construct, economical in its implementation with little constraint on the working dimensions in height.

The specified technical result when using the utility model is achieved by the fact that in the known device for reinforcing reinforced concrete floor panels, which additionally includes steel transverse beams, a feature is that the transverse reinforcement beams are supported on the lower shelves of the longitudinal beams of the building frame, while the transverse beams summed up from the bottom of the reinforced floor panels with a gap between the top of the transverse beams and the bottom of the reinforced floor panels, the transverse beams are equipped with screw spacers bubbled devices that are installed in the gap between the bars and the floor panel; after the introduction of spacers into operation, the distribution thrust plates and the transverse reinforcement beams are connected together by segments of corners or plates; the gap between the floor panels and the transverse beams is filled with structural reinforcement concrete in the form of a concrete key with indirect reinforcement; shelves and ribs of steel beams

reinforcements are covered with protective materials of the required thickness from the condition of fire resistance of floor beams as load-bearing elements of a building.

Another feature is that the cross-sectional dimensions of the steel rolling profile of the transverse beam are taken from the conditions for calculating the load-bearing capacity of the device for reinforcement during its installation.

The cross-sectional dimensions of the reinforced concrete crossbeam with a steel rolling profile used as rigid reinforcement are taken from the conditions for calculating the load-bearing capacity of the device for reinforcing floor panels.

The screw spacer includes the top shelf of the steel rolling profile as a support table, distribution plates, spacer studs / stud bolts, thrust nuts, washers, and locknuts.

The dimensions of the stud / stud bolt and thrust nut are taken from the operating conditions of the compressed steel bar to the design reinforcement load. Spacers are installed along the width of the lower shelf of each floor panel at least at two points.

Spacer distribution plates are adopted split for each reinforced floor panel or solid across the width of several reinforced floor panels. Spacer distribution plates for each reinforced floor panel are adopted as integral or integral across the width of the plate.

The gap between the upper shelf of the steel transverse beams and the bottom of the reinforced floor panels is adopted at least 50 mm high.

The gap between the floor panels and the steel cross beams in the form of a reinforcement key is filled with structural concrete with a compressive strength class not lower than the concrete class of reinforced concrete floor panels.

The key from structural reinforcement concrete has indirect reinforcement in the form of welded bent nets or bent zigzag nets with protrusions beyond the side

edges of a concrete key for the subsequent fastening of a wire or mesh winding and applying a predetermined thickness of fire-retardant material to it.

As fire-retardant materials for facing steel beams, heat-insulating concrete, mineral wool, bricks and stucco on reinforcing mesh were used.

Grids of indirect reinforcement of concrete. Strength keys are made of steel of classes A240 (A-I) ⌀ (6 ÷ 14) mm; А300 (A-II) ⌀ (10 ÷ 14) mm; A400 (A-III) ⌀ (6 ÷ 8) mm, or steel of class BP-I ⌀ (3 ÷ 5) mm.

The diameters of the studs and stud bolts and their number are taken according to the calculation of the load-bearing capacity of steel compressed elements depending on the amount of unloading of the floor panels.

Spacer stud bolts are joined to the thrust plate by a continuous welded joint. Spacer studs are articulated with a thrust plate equipped with a socket, a fixed threaded stud connection.

The surfaces of the distribution steel plates that are articulated with the overlapping panels and subjected to firing by burners are recessed “into the juice” of a 1: 3 cement-sand plastic mortar with squeezing.

The height of the weld connecting the elements of the device for reinforcement is taken as calculated for bending and shear, but not less than 6 mm.

After the introduction of the spacer, the support table and the elements of the distribution plates are connected in the middle of the length of the distribution plates by a metal plate or a corner piece.

The class of additionally laid concrete in compression strength is taken equal to the class of reinforced floor panels, but not less than B 15.

The causal relationship between the totality of features and the technical result of the work is as follows.

Using the proposed device for reinforcing makes it possible to increase the load-bearing capacity by 4–8 times and the actual fire resistance limit by 3–5 times based on the loss of the load-bearing capacity of reinforced concrete floor panels.

Smooth unloading of damaged panels using screw spacers eliminates the occurrence of shock loads and mechanical stresses - this increases the safety of damaged structures during emergency recovery operations.

The introduction of reinforcing devices spacers and indirectly reinforced concrete keys reliably connect reinforced panels and an elastic-reinforced reinforcement structure.

The support of the steel transverse beams of the reinforcement device on the longitudinal beams of the building frame eliminates the need for punching through holes and holes in the floor panels.

Filling constructive concrete with a gap between the steel transverse reinforcement beam and the reinforced floor panels turns the metal reinforcement beam into a reinforced concrete structure with rigid reinforcement.

The regulation of the unloading of the floor panels allows a better restoration of the operational characteristics (bearing capacity and fire resistance) of reinforced concrete panels with the help of additionally brought transverse beams.

The drawings show:

Figure 1 shows the node supporting the steel transverse beam, summed up from the bottom of reinforced concrete floor panels, with the longitudinal beam of the building frame (section 1-1 in figure 2): 1 - amplified floor panel; 2 - elements of the distribution plate; 3 - thrust plate; 4 - studs / stud bolts with persistent thread; 5 - steel transverse reinforcement beam; 6 - steel longitudinal girder; 7 - nut high persistent with a washer; 8 - a lock-nut; 9 - a piece of corner, plate; 10 - concrete key; 11 - indirect reinforcement.

Figure 2 and 3 shows a schematic assembly drawing of reinforcing reinforced concrete floor slabs by summing the transverse beam in the form

elastic support (sections 2-2 and 3-3): 1 - reinforced floor panel; 2 - elements of a distribution plate; 3 - thrust plate; 4 - studs / stud bolts with persistent thread; 5 - steel transverse reinforcement beam; 6 - steel longitudinal girder; 9 - a piece of corner plate.

Figure 4-6 shows a diagram of a steel transverse beam of a reinforcement device in the form of a rolling I-beam (sections 4-4; 5-5 and 6-6).

Figure 7 shows the thrust device of the elastic support structure of reinforcement: 3 - thrust plate; 4 - studs / stud bolts with persistent thread; 5 - steel transverse reinforcement beam; 7 - nut high persistent with a washer; 8 - a lock-nut; 9 - a piece of corner plate.

On Fig shows a mesh "zigzag" for indirect reinforcement of concrete keys: 11 - indirect reinforcement.

Information confirming the possibility of using the utility model to obtain the above technical result.

Inspection of a building area of 100 m ² damaged by short-term (0.3 ÷ 0.5 hours} exposure to high temperatures (800 ± 50) C, it was found that the overlapping panels to be reinforced consist of multi-hollow reinforced concrete panels with a span of 7.2 m, width 1 , 2 and 1.5 m; the cross-sectional height of the panels is 220 mm.

The reinforcement device for a group of damaged panels is designed in terms of the building site in the form of two additional transverse beams for reinforced concrete panels with a supporting metal rod in the form of I-beams No. 18 (b × h × d × δ = 180 × 90 × 5.1 × 8.1 mm). Strengthening transverse beams are supported on the lower flanges of longitudinal I-beams No. 30 Ш1 (b × h × d × δ = 291 × 135 × 6.5 × 10.1 mm) with a gap Z = 100 mm to the bottom of the panels.

The space between the upper shelf of the steel transverse reinforcement beam 5 and the bottom of the reinforced floor panels 1 in the form of a key is filled with concrete of class B30 for compressive strength; the concrete key 10 is reinforced with indirect reinforcement 11 in the form of curved zigzag nets: reinforcement class BP-I ⌀ 5 mm; length

nets of 1.2 and 1.5 m, pitch of branches 50 ÷ 80 mm. The tensioner includes a support table (upper shelf of the transverse beam) with holes ⌀ 20 mm; e = 50 mm; paired thrust elements of the distribution plate 2 with a length of 800 and 1000 mm, a thickness of 20 mm are installed under each reinforced floor panel 1 with a width of 1.2 and 1.5 m, spacer stud bolts with a threaded thread 4 4 16 mm, with a high thrust nut 7 D = 40 mm, h = 22 mm, with a washer with a thickness of S = 3 mm, D _w = 44 mm; with lock nut 8 D ₁ = 40 mm, h ₁ = 12 mm. The device is intended for implementation at Avers CJSC (Samara, 2008).

Information sources

1. Ilyin N.A. Patent Pat. 2 119023 RU, MPK-6 Е04С 5/08. Reinforcing product / Ilyin N.A .; application No. 96115626/03; from 07/26/96; publ. 09/20/98, Bull. No. 26.

2. Onufriev N.M. Reinforcement of reinforced concrete structures of industrial buildings and structures / N.M. Onufriev. - L., - M.: Stroyizdat, 1965, - 342 s; (see p. 90-91, Fig. 33, a).

3. Recommendations for assessing the condition and strengthening of building structures of industrial buildings and structures. / NIIISK. - M .: Stroyizdat, 1989, - 105 s (see p. 28, p. 4.30, fig. 2, D; p. 35, p. 4.35).

Claims (20)

1. A device for reinforcing reinforced concrete floor slabs, including additionally brought steel transverse beams, characterized in that the transverse reinforcing beams are supported on the lower shelves of the longitudinal beams of the building frame, while the transverse beams are summed up from the bottom of the reinforced overlapping panels with a gap between the top of the transverse beams and the bottom of the reinforced floor panels, the cross beams are equipped with screw spacers that are installed in the gap between the transverse beams and the floor panels; after the introduction of the spacers into operation, the distribution stop plates and the transverse reinforcement beams are connected together by segments of corners or plates; the gap between the floor panels and the transverse beams is filled with structural reinforcement concrete in the form of a concrete key with indirect reinforcement; shelves and ribs of steel reinforcement beams are covered with protective materials of the required thickness from the condition of fire resistance of floor beams as load-bearing elements of a building. 2. The device according to claim 1, characterized in that the cross-sectional dimensions of the steel rolling profile of the transverse beam are taken from the conditions for calculating the load-bearing capacity of the device for reinforcement during its installation. 3. The device according to claim 1, characterized in that the cross-sectional dimensions of the reinforced concrete transverse beam with a steel rolling profile used as rigid reinforcement are taken from the conditions for calculating the load-bearing capacity of the device for reinforcing floor panels. 4. The device according to claim 1, characterized in that the screw spacer includes the upper shelf of the steel rolling profile as a support table, distribution plates, spacers / stud bolts, thrust nuts, washers and locknuts. 5. The device according to claim 1, characterized in that the dimensions of the stud / bolt-stud and thrust nuts of the spacer are taken from the operating conditions of the compressed steel rod to the design reinforcement load. 6. The device according to claim 1, characterized in that the spacers are installed across the width of the lower shelf of each floor panel at least at two points. 7. The device according to claim 1, characterized in that the distribution plates of the spacer are split for each reinforced floor panel or integral across the width of several reinforced floor panels. 8. The device according to claim 1, characterized in that the distribution plates of the spacer for each reinforced floor panel are made integral or composite across the width of the plate. 9. The device according to claim 1, characterized in that the gap between the upper shelf of the steel transverse beams and the bottom of the reinforced floor panels is adopted at least 50 mm high. 10. The device according to claim 1, characterized in that the gap between the floor panels and the steel transverse beams in the form of a gain key is filled with structural concrete with a compressive strength class not lower than the concrete class of reinforced concrete floor panels. 11. The device according to claim 1, characterized in that the key of structural reinforced concrete has indirect reinforcement in the form of welded bent nets or bent nets “zigzag” with protrusions beyond the side faces of the concrete dowel for subsequent fastening of the winding from a wire or mesh and applying to it the specified thickness of the flame retardant material. 12. The device according to claim 1, characterized in that heat-insulating concrete, mineral wool, bricks and stucco are used as fire retardant materials for facing steel beams. 13. The device according to claim 1, characterized in that the grids of indirect concrete reinforcement of the reinforcement key are made of steel of classes A240 (A-I) ⌀ (6 ÷ 14) mm; А300 (A-II) ⌀ (10 ÷ 14) mm; A400 (A-III) ⌀ (6 ÷ 8) mm, or steel of class BP-I ⌀ (3 ÷ 5) mm. 14. The device according to claim 1, characterized in that the diameters of the studs and bolts-studs of the spacer and their number are taken according to the calculation of the bearing capacity of steel compressed elements depending on the amount of unloading of the floor panels. 15. The device according to claim 1, characterized in that the spacer bolts-studs are connected to the thrust plate by a continuous welded joint. 16. The device according to claim 1, characterized in that the spacers are articulated with a thrust plate equipped with a socket, a fixed threaded stud connection. 17. The device according to claim 1, characterized in that the surfaces of the distribution steel plates mating with the overlapping panels subjected to firing by the burners are recessed into the juice of a 1: 3 cement-sand plastic mortar with squeezing. 18. The device according to claim 1, characterized in that the height of the weld connecting the elements of the device for reinforcement, is taken as calculated for bending and shear, but not less than 6 mm 19. The device according to claim 1, characterized in that after the introduction of the spacer, the support table and the elements of the distribution plates are connected in the middle of the length of the distribution plates by a metal plate or a corner piece. 20. The device according to claim 1, characterized in that the class of additionally laid concrete in compressive strength is taken equal to the class of reinforced floor panels, but not less than B 15.